University of Utah researchers have found that the structure of an insulin molecule produced by predatory cone snails may be an improvement over current fast-acting therapeutic insulin. The finding suggests that the cone snail insulin, produced by the snails to stun their prey, could begin working in as few as five minutes, compared with 15 minutes for the fastest-acting insulin currently available. Biologist Helena Safavi, co-author on a paper describing the cone snail insulin published September 12 in Nature Structural & Molecular Biology, says that studying complex venom cocktails can open doors to new drug discoveries. “You look at what venoms animals make to affect the physiology of their prey, and you use that as a starting point,” she says. “You can get new ideas from venoms. To have something that has already been evolved—that’s a huge advantage.” Along with colleagues from Australia, U biochemists Danny Chou and Maria Disotuar, and biologists Joanna Gajewiak and Baldomero Olivera contributed to the study.
Learn about our two Decals!
Click here to find out more about our Fall Bioinspired Design Decal and our Spring Bioinspired Design in Action Decal – ALL MAJORS are welcome.Berkeley BioDesign Community
Click here to learn about the BioD: Bio-Inspired Design @ Berkeley student organization or here to signup for more info.
I imagine that the neurological circuits underlying these processes are governed by both 2d spacing maps with their brains as…
to reduce the impact of car accidents, it may be possible to study the force diverting physics of cockroaches to…
you see this type of head-bobbing stability in many avian creatures related to pigeons like chickens. the head ability to…
not like they taught horses how to run! this is an example of convergent evolution where both sea creatures and…
The brain functions in a similar way with neuronal connections. our brains are able to utilize the multiplicity of connections…